Impact of Surfactants on Skin Penetration of Dexpanthenol.

OBJECTIVE: It was the aim of this study to evaluate the impact of nonionic and ionic surfactants on skin penetration of dexpanthenol. METHODS: The relative potency of three surfactants (two nonionic and one ionic) as enhancers in the permeability of a series of compounds was investigated. The influence of the enhancers was also studied. For this purpose, porcine abdominal skin was prepared and mounted on Franz diffusion cells, while different mixtures of Dexpanthenol containing Tween®85, SDS and Span®80 in concentrations of 0.5%, 1%, 2%, 5% (m/V) were evaluated in terms of their permeation enhancing effect. The amount of permeated drug was determined via HPLC analysis. Moreover, the cytotoxicity and skin irritating effect of the compounds were tested on Caco-2 cells. RESULTS: The cytotoxicity profile of Dexpanthenol showed no toxicity to the cells over 1 and 3 h of incubation. The permeation was evaluated over a time period of 180 min, whereas a ranking of SDS> Span>Tween could be determined as permeation enhancer. CONCLUSION: Taking these findings into consideration, concentration of 1% (w/w) surfactant showed the most promising results. The increase in flux based on low concentrations of enhancer was ascribed to their ability to reduce skin´s barrier and improve drug permeation. The results showed that the nature of enhancer greatly impacts cutaneous barrier impairment.

Powder flow analysis: A simple method to indicate the ideal amount of lactose fines in dry powder inhaler formulations.

Many efforts have been made in the past to understand the function of lactose fines which are given as a ternary component to carrier-based dry powder inhaler formulations. It is undisputed that fines can significantly improve the performance of such formulations, but choosing the right amount of fines is a crucial point, because too high concentrations can have negative effects on the dispersion performance. The aim of this study was to indicate the optimal concentration of fines with a simple test method. For this purpose, mixtures with salbutamol sulfate and two different lactose carriers were prepared with a high shear mixer, measured with a FT4 powder rheometer and tested for fine particle delivery with two different inhaler devices. A correlation between the fluidization energy, measured with the aeration test set up, and the fine particle fractions (FPF) could be proven. This also applied for the aeration ratio, as well as the permeability of the powder samples. In addition, drug-free mixtures hardly differed in their rheological properties from mixtures containing the active pharmaceutical ingredient (API), which indicates that the method could be suitable for cost-saving screening trials. Furthermore, important aspects that explain the function of fines, such as the saturation of active sites, the formation of agglomerates and an increase in fluidization energy, could be shown in this study.

The influence of high shear mixing on ternary dry powder inhaler formulations.

The blending process is a key step in the production of dry powder inhaler formulations, but only little is known about the influence of process parameters. This is especially true for high shear blending of ternary formulations. For this reason, this study aims to investigate the influence of high shear mixing process parameters (mixing time and rotation speed) on the fine particle fraction (FPF) of ternary mixtures when using budesonide as model drug, two different carrier materials and two different mixing orders. Prolonged mixing time and higher rotation speeds led to lower FPFs, possibly due to higher press-on forces acting on the active pharmaceutical ingredients (API). In addition, a clear correlation between the energy consumption of the blender (the energy input into the blend) and the reduction of the FPF could be shown. Furthermore blending the carrier and the fines before adding the API was also found to be favorable.

Evaluation of the impact of multivalent metal ions on the permeation behavior of Dolutegravir sodium.

Interactions between active pharmaceutical ingredients (APIs) and polyvalent cations are an important factor within drug absorption in the gastrointestinal tract. Dolutegravir sodium, as a second-generation integrase stand transfer inhibitor for the treatment of HIV was investigated regarding chelation with Al(3+), Ca(2+), Fe(3+), Mg(2+ )and Zn(2+) ions at three different molar ratios. Furthermore, the influence of drug-ion chelates on the permeability of the drug across two intestinal membrane models was analyzed. For this purpose, Caco-2 monolayer model and Ussing chamber technique utilizing freshly excited rat intestinal mucosa were chosen and a buffer system without additional Mg(2+) and Ca(2+) ions was tested regarding cell detachment. The addition of polyvalent cations in an equal molar ratio to the drug solution decreased the dissolved drug by at least 11%. An increased multivalent cation concentration in a ratio of 1:10 afforded an API drop in the solution of at least 88% with the exception of Mg(2+). In particular, Dolutegravir sodium was chelated with iron ions to nearly 100%. Overall, the higher the amount of metal ions in the solution, the lower was the detected amount of the drug. The permeation experiments across the Caco-2 monolayer and the rat intestinal mucosa pointed out that the addition of AlCl3, CaCl2 and ZnCl2 in a molar ratio of 10:1 to the drug led to significantly decreased drug permeation. According to these results the co-administration of Al(3+), Ca(2+ )or Zn(2+ )as well as of supplementary medications containing these polyvalent ions is in case of oral Dolutegravir delivery not recommended.

Mucus permeating thiolated self-emulsifying drug delivery systems.

CONTEXT: Mucus represents a critical obstacle for self-emulsifying drug delivery systems (SEDDS) targeting the epithelial membrane site. OBJECTIVE: The aim of the study was the development of a novel SEDDS to overcome the mucus barrier. MATERIALS AND METHODS: Two novel conjugates N-dodecyl-4-mercaptobutanimidamide (thiobutylamidine-dodecylamine, TBA-D) and 2-mercapto-N-octylacetamide (thioglycolicacid-octylamine, TGA-O) were synthesized, incorporated into SEDDS and analyzed for stability, cytotoxicity and physico-chemical characteristics using dynamic light scattering. Mucus interaction studies were performed using in vitro assays based on multiple particle tracking, rotational silicone tubes and rheology. RESULTS AND DISCUSSION: TBA-D was synthesized using dodecylamine and iminothiolane as thiol precursor (yield=55 ± 5%). TGA-O was obtained via crosslinking of octylamine with SATA ((2,5-dioxopyrrolidin-1-yl) 2-acetylsulfanylacetate) (yield=70 ± 6%). The chemical structure of target compounds was confirmed via NMR analysis. The thiol-conjugates were incorporated in an amount of 3% (m/m) into SEDDS (Cremophor EL 30%, Capmul MCM 30%, Captex 355 30% and propylene glycol 10%), namely thiolated SEDDS leading to a droplet size around 50 nm and zeta potential close to 0 mV. Thiolated SEDDS with an effective diffusion coefficient 〈Deff〉 of up to 0.871 ± 0.122 cm(2) s(-1) × 10(-9) were obtained. Rotational silicone studies show increased permeation of the thiolated SEDDS A in comparison with unthiolated control. Rheological studies confirmed the mucolytic activity of the thiol-conjugates which differed only by 3% from DTT (dithiothreitol) serving as positive control. CONCLUSION: Low molecular weight thiol-conjugates were identified to improve the mucus permeation, leading to highly efficient mucus permeating SEDDS, which were superior to conventional SEDDS and might thus be a new carrier for lipophilic drug delivery.

Self-nanoemulsifying drug delivery systems as novel approach for pDNA drug delivery.

It was the aim of this study to investigate a novel strategy for oral gene delivery utilizing a self-nanoemulsifying drug delivery system (SNEDDS). After hydrophobic ion pairing a plasmid was incorporated into SNEDDS. The mean droplet size of resulting nanoemulsions was determined to be between 45.8 and 47.5 nm. A concentration dependent cytotoxicity of the formulations was found on HEK-293 cells via MTT assay. Degradation studies via DNase I showed that incorporation into SNEDDS led to significantly, up to 8-fold prolonged resistant time against enzymatic digestion compared to naked pDNA and pDNA-lipid complexes. Transfection studies carried out revealed a significantly improved transfection compared to naked pDNA. Further, no decrease in transfection efficiency compared to transfection using Lipofectin(®) transfection reagent was observed.

Synthesis and in vitro characterization of a novel S-protected thiolated alginate.

The object of this study was to synthesize and characterize a novel S-protected thiolated polymer with a high degree of modification. In this regard, an alginate-cysteine and an alginate-cysteine-2-mercaptonicotinic acid conjugate were synthesized. To achieve a high coupling rate of the thiol group bearing ligand cysteine to the polymer, the carbohydrate was activated by an oxidative ring opening with sodium periodate followed by a reductive amination to bind the primary amino group of cysteine to resulting reactive aldehyde groups. The obtained thiolated polymer displayed 1561±130µmol thiol groups per gram polymer. About one third of these thiol groups were S-protected by the implementation of a thiol bearing aromatic protection group via disulfide bond formation. Test tablets of both modified polymers showed improved stability against oxidation in aqueous environment compared to the unmodified alginate and exhibit higher water-uptake capacity. Rheological investigations revealed an increased viscosity of the S-protected thiolated polymer whereat the thiolated non S-protected polymer showed gelling properties after the addition of hydrogen peroxide. The mucoadhesive properties could be improved significantly for both derivatives and no alteration in biocompatibility tested on Caco-2 cell monolayer employing an MTT assay could be detected after modification. According to these results, both new derivatives seem promising for various applications.

Thiolated alkyl-modified carbomers: Novel excipients for mucoadhesive emulsions.

The aim of this study was the design and evaluation of mucoadhesive emulsifying polymeric excipients. Three thiol bearing ligands with increasing pKa values of their sulfhydryl group, namely 4-aminothiophenol (pKa=6.86), l-cysteine (pKa=8.4) and d/l-homocysteine (pKa=10.0) were coupled to the polymeric backbone of alkyl-modified carbomer (PA1030). Resulting conjugates displayed 818.5µmol 4-aminothiophenol, 698.5µmol cysteine and 651.5µmol homocysteine per gram polymer and were evaluated regarding the reactivity of thiol groups, emulsifying and mucoadhesive properties. In general, the synthesized conjugates showed a pH dependent reactivity, whereby the fastest oxidation occurred in PA1030-cysteine, as almost no free thiol groups could be detected after 120min. Emulsification of medium chain triglycerides was feasible with all synthesized conjugates leading to oil-in-water-emulsions. Emulsions with PA1030-cysteine displayed the highest stability and the smallest droplet size among the tested formulations. Oxidation and consequently cross-linking of the thiomers prior to the emulsification process led to an overall decreased emulsion stability. Evaluating mucosal residence time of thiomer emulsions on porcine buccal mucosa, a 9.2-fold higher amount of formulation based on PA1030-cysteine remained on the mucosal tissue within 3h compared to the unmodified polymer. According to these results, the highest reactive ligand l-cysteine seems to be most promising in order to obtain thiolated polymers for the preparation of mucoadhesive o/w-emulsions.

Preactivated thiolated poly(methacrylic acid-co-ethyl acrylate): synthesis and evaluation of mucoadhesive potential.

The study was aimed to developed and investigate a novel polymer for intestinal drug delivery with improved mucoadhesive properties. Therefore Eudragit® L 100-55 (poly(methacrylic acid-co-ethyl acrylate)) was thiolated by covalent attachment of L-cysteine. The immobilized thiol groups were preactivated by disulfide bond formation with 2-mercaptonicotinic acid. Resulting derivative (Eu-S-MNA) was investigated in terms of mucoadhesion via three different methods: tensile studies, rotating cylinder studies and rheological synergism method, as well as water-uptake capacity and cytotoxicity. Different derivatives were obtained with increasing amount of bound L-cysteine (60, 140 and 266 µmol/g polymer) and degree of preactivation (33, 45 and 51 µmol/g polymer). Tensile studies revealed a 30.5-, 35.3- and 52.2-fold rise of total work of adhesion for the preactivated polymers compared to the unmodified Eudragit. The adhesion time on the rotating cylinder was prolonged up to 17-fold in case of thiolated polymer and up to 34-fold prolonged in case of the preactivated polymer. Rheological synergism revealed remarkable interaction of all investigated modified derivatives with mucus. Further, water-uptake studies showed an over 7h continuing weight gain for the modified polymers whereat disintegration took place for the unmodified polymer within the first hour. Cell viability studies revealed no impact of modification. Accordingly, the novel preactivated thiolated Eudragit-derivative seems to be a promising excipient for intestinal drug delivery.

In vivo evaluation of an oral self-microemulsifying drug delivery system (SMEDDS) for leuprorelin.

The objective of this study was to develop a self-microemulsifying drug delivery system (SMEDDS) for the model peptide drug leuprorelin to prove a protective effect against luminal enzymatic metabolism. In order to incorporate leuprorelin into microemulsion droplets (o/w), the commercially available hydrophilic leuprolide acetate was modified by hydrophobic ion paring with sodium oleate. The obtained hydrophobic leuprolide oleate was dissolved in the SMEDDS formulation (30% (m/m) Cremophor EL, 30% (m/m) Capmul MCM, 10% (m/m) propylene glycol and 30% (m/m) Captex 355) in a concentration of 4 mg/g showing a mean droplet size of 50.1 nm when dispersed in a concentration of 1% (m/v) in phosphate buffer pH 6.8. The microemulsion was able to shield leuprolide oleate from enzymatic degradation by trypsin and α-chymotrypsin, so that after 120 min 52.9% and 58.4%, respectively, of leuprolide oleate were still intact. Leuprolide acetate dissolved in an aqueous control solution was completely metabolized by trypsin within 60 min and by α-chymotrypsin within 5 min. Moreover, an in vivo study in rats showed a 17.2-fold improved oral bioavailability of leuprolide oleate SMEDDS compared to a leuprolide acetate control solution. This is the first time, to our knowledge, that hydrophobic ion pairing is utilized in order to incorporate a peptide drug in SMEDDS and evidence of a protective effect of oil-in-water (o/w) microemulsion droplets against enzymatic degradation of a peptide drug was provided. According to these results, the system could be likely a novel platform technology to improve the oral bioavailability of peptide drugs.

Synthesis and characterization of pH tolerant and mucoadhesive (thiol-polyethylene glycol) chitosan graft polymer for drug delivery.

The objective of this study was to generate a water-soluble thiolated chitosan to enable the permeation-enhancing effect of chitosan at pH of at least 5.5 without losing the advantages of improved mucoadhesive properties. Therefore, the thiol-bearing polyoxyethylene ligand {O-(3-carboxylpropyl)-O'-[2-[3-mercaptopropionylamino)ethyl]-polyethyleneglycol} was conjugated via amide bond formation to the amino group of chitosan. Resulting novel chitosan derivative (Chito-PEG-SH) exhibited 250 µmol free thiol groups per gram polymer. By the attachment of the thiol-bearing PEG ligand, an improvement of permeation-enhancing effect on rat intestine (2.7-fold improvement) as well as on a Caco-2 monolayer model (1.9-fold improvement) could be found. Cytotoxicity studies on Caco-2 cells revealed no change in biocompatibility. Mucoadhesion was improved 3.1-fold by the formation of disulfide bonds with mucus glycoproteins. The mucoadhesive effect of Chito-PEG-SH turned out to be similar to thiolated chitosan and more pronounced than mucoadhesive properties of unmodified chitosan. The graft polymer is soluble in water and aqueous solutions over a broad pH range. In aqueous media, the novel polymer does not precipitate at pH of 8.6 or less. According to these results, Chito-PEG-SH might show potential as auxiliary agent in oral drug delivery where its solubility even up to pH 8 is likely beneficial.

Development and in vitro evaluation of a buccal drug delivery system based on preactivated thiolated pectin.

The aim of this study was to evaluate the potential of preactivated thiolated pectin (Pec-Cys-MNA) for buccal drug delivery. Therefore, a gel formulation containing this novel polymer and the model drug lidocaine was prepared and investigated in vitro in terms of rheology, mucoadhesion, swelling behavior and drug release in comparison to formulations based on pectin (Pec) and thiolated pectin (Pec-Cys). Both pectin derivatives showed gel formation without addition of any other excipient due to self-crosslinking thiol groups. Under same conditions, pectin did not show gel formation. Viscosity of Pec-Cys-based formulation increased 92-fold and viscosity of Pec-Cys-MNA-based formulations by 4958-fold compared to pectin-based formulation. Gels did not dissolve in aqueous environment during several hours and were able to take up water. Mucoadhesion of pectin on buccal tissue could be improved significantly, value of total work of adhesion increased in the following rank order: Pec-Cys-MNA > Pec-Cys > Pec. The retention time of a model drug incorporated in gel formulations on buccal mucosa under continuous rinsing with phosphate-buffered saline was prolonged, after 1.5 h 3-fold higher amount of a model drug was to be found on tissue after application of Pec-Cys-MNA-based formulation compared to pectin-based and 2-fold compared to Pec-Cys-based formulation. The Pec-Cys-MNA-based gel showed a more sustained release of lidocaine than Pec-Cys-based gel, whereas pectin solution revealed an immediate release. According to these results, the self-crosslinking pectin-derivative is a promising tool for buccal application.

Synthesis and in vitro characterization of entirely S-protected thiolated pectin for drug delivery.

The study was aimed to synthesize a thiolated polymer (thiomer) that is resistant to oxidation in solutions above pH 5. In order to protect a pectin-cysteine conjugate against premature oxidation, the thiomer was S-protected by a disulfide connected leaving group. Therefore, 2-mercaptonicotinic acid was first coupled to L-cysteine by a disulfide exchange reaction and the purified product was subsequently attached to pectin by a carbodiimide mediated amid bond formation. The obtained fully S-protected thiolated pectin was in vitro characterized with respect to co- and mucoadhesive properties and stability toward oxidation. The results indicated a 1.8-fold and 2.3-fold enhanced disintegration time at pH 6.8 of the S-protected thiolated pectin (Pec-Cys-MNA) compared to thiolated pectin (Pec-Cys) and unmodified pectin (Pec). Moreover, rheological measurements of polymer/mucus mixtures showed a 1.6-fold (compared to Pec-Cys) and 6.7-fold (compared to Pec) increased dynamic viscosity of Pec-Cys-MNA. On the other hand, in the presence of a strong oxidizing agent such as H2O2 (0.3% v/v), no increase in viscosity of Pec-Cys-MNA could be observed. A 6-month experiment also demonstrated the long-term stability of a liquid formulation based on Pec-Cys-MNA. Further investigations proved that the first time all thiol groups on a thiolated polymer could be protected owing to the novel synthesis. Accordingly, these features may help to develop thiomer based liquid or gel formulations targeting mucosal surfaces such as nasal, ocular or vaginal drug delivery systems.

Preactivated thiomers: evaluation of gastroretentive minitablets.

The object of this study was to evaluate the potential of a recently developed preactivated thiolated pectin derivative as mucoadhesive excipient in drug delivery to the gastric cavity. Pectin (Pec) was chemically modified with L-cysteine (Cys). The free thiol groups of resulting thiomer were activated with 2-mercaptonicotinic acid (MNA) in order to improve stability and reactivity of attached thiol groups over a broad pH range. Multiunit dosage form properties of the resulting conjugate (Pec-Cys-MNA) were compared to unmodified pectin and the intermediate thiolated using rosuvastatin calcium as a model drug in loaded minitablets. Obtained results were compared with unmodified pectin and the intermediate thiolated pectin. Approximately half of attached thiol groups (507 µmol/g polymer) have been preactivated. Minitablets were evaluated regarding mucoadhesive properties, hardness, disintegration behavior, swelling characteristics and release of rosuvastatin calcium. Mediated by covalent bonds between the polymer and cysteine-rich subdomains in mucus, total work of adhesion increased more than 5-fold. The modification had no impact on hardness of compressed tablets but implementation of the aromatic ligand went along with reduction in hydrophilic properties. Disintegration time was prolonged more than 2-fold while water uptake capacity increased. Weight gain for Pec-Cys-MNA was at least 16-fold. Further, a sustained release of rosuvastatin calcium over 36 h was determined. Neither biodegradability nor CaCo-2 cell viability was affected. The study shows that Pec-Cys-MNA is a promising excipient for the development of mucoadhesive gastric dosage form.

Thiomers and thiomer-based nanoparticles in protein and DNA drug delivery.

INTRODUCTION: Thanks to advances in biotechnology, more and more highly efficient protein- and DNA-based drugs have been developed. Unfortunately, these kinds of drugs underlie poor non-parental bioavailability. To overcome hindrances like low mucosal permeability and enzymatic degradation polymeric excipients are utilized as drug carrier whereat thiolated excipients showed several promising qualities in comparison to the analogical unmodified polymer. AREAS COVERED: The article deals with the comparatively easy modification of well-established polymers like chitosan or poly(acrylates) to synthesize thiomers. Further, the recently developed "next generation" thiomers e.g. preactivated or S-protected thiomers are introduced. Designative properties like mucoadhesion, uptake and permeation enhancement, efflux pump inhibition and protection against enzymatic degradation will be discussed and differences between first and next generation thiomers will be pointed out. Additionally, nanoparticles prepared with thiomers will be dealt with regarding to protein and DNA drug delivery as thiomers seem to be a promising approach to avoid parenteral application. EXPERT OPINION: Properties of thiomers per se and results of in vivo studies carried out so far for peptide and DNA drugs demonstrate their potential as multifunctional excipients. However, further investigations and optimizations have to be done before establishing a carrier system ready for clinical approval.